Nuclearmagnetic resonance studies of selectively hindered internal

HINDERED MOTION OF ENZYME-BOUND

SUBSTRATE ANALOGS

Nuclear Magnetic Resonance Studies of Selectively Hindered Internal Motion of Substrate Analogs at the Active Site of Pyruvate Kinaset Thomas Nowaki and Albert S. Mildvan*

The interactions of muscle pyruvate kinase with three competitive analogs of phosphoenolpyruvate, D- and L-phospholactate and phosphoglycolate, were studied by measuring the longitudinal (l/Tl) and transverse (l/Tz) relaxation rates of the protons and phosphorus of the analogs. The enzyme alone or in the presence of Mg*+elicits a stereoselective dipolar effect on the relaxation rates of the methyl protons of L-phospholactate to a much greater extent than on D-phospholactate. The relaxation rates yield a correlation time (7,)which is a typical time constant for hindered methyl rotation on the bound L isomer (7, = 1.7 X sec, E,,, = 1.8 kcal/mole). The hindrance of methyl rotation is presumably due to steric interaction of the methyl group of the L ABSTRACT:

T

he earliest nuclear magnetic resonance (nmr) studies of the binding of small molecules to macromolecules made use of the increased relaxation rates of the nuclei of the ligand when it binds to the macromolecule. Such dipolar effects on nmr line widths were used by Jardetzky and coworkers to study the interaction of various antibiotics and sulfonamides with serum albumin (Jardetzky, 1964; Jardetzky and WadeJardetzky, 1965) and have since been extended to studies of the binding of the coenzyme NAD to dehydrogenases (Hollis, 1967) and of substrate analogs to chymotrypsin (Sykes, 1969a,b), aspartate transcarbamylase (Sykes et a/., 1970), lysozyme (Sykes, 1969a,b; Studebaker et al., 1971; Raftery et a[., 1968, 1969), and carbonic anhydrase (Lanir and Navon, 1971). Although diamagnetic effects on relaxation rates are usually much smaller, and more difficult to interpret than paramagnetic effects (Jardetzky, 1964), they can yield structural information when supplemented by studies of the structure of the complex by independent methods such as X-ray diffraction or paramagnetic probe experiments. Thus, the diamagnetic effect of lysozyme on CY- and P-N-acetylglucosamine in solution were interpreted in terms of the crystal structure of this enzyme (Blake et a/., 1965, 1967; Phillips, 1967; Phillips and Sarma, 1967) where the observed shifts were explained by proximity to the aromatic residue, tryptophan-108, and the larger dissociation constant of the CY anomer can be explained by a steric interaction between the methyl group of the

t From the Institute for Cancer Research, Fox Chase, Philadelphia, Pennsylvania 19111. Received March 16, 1972. This work was supported by U. S. Public Health Service Grants AM-13351, CA-06927, RR00542 (for use of nmr equipment located at the University of Pennsylvania) and RR-05539 from the National Institutes of Health, GB27739X (previously GB-8579) from the National Science Foundation, and by an appropriation from the Commonwealth of Pennsylvania. $ A postdoctoral fellow of the National Institutes of Health.

isomer with the group on the enzyme which protonates phosphoenolpyruvate. Little or no hindrance of rotation of the methyl group of D-phospholactate is detected (7, 5 5 X 10-10 sec). With phosphoglycolate, hindered motion of the methylene protons (7, 1.1 X sec) and the phosphate (rC= 6.6 X 1 0 P sec) are detected. The correlation time for phosphorus is indistinguishable from the rotation time calculated for the entire enzyme molecule (7, = 5.6 X 1 0 P sec). The 7, values thus indicate progressively greater immobilization of the bound analogs as one approaches the reaction center phosphorus. Such immobilization or “freezing” of bound substrates at the reaction center would permit orientational or entropic effects to operate in enzyme catalysis.

>

inhibitor and residues 52 and 109 at the active site of lysozyme (Sykes, 1969a,b). The present work follows from our earlier observation (Nowak and Mildvan, 1970) that the compounds, L-phospholactate and D-phospholactate, analogs of the substrate, P-enolpyruvate, bind to the pyruvate kinase-Mn complex with very different affinities. The 20-fold weaker binding of phospholactate, as compared with its stereoismer, D-phospholactate, was explained in terms of the stereochemistry of the pyruvate kinase reaction (Rose, 1970) by proposing van der Waals interaction of the methyl group of the L isomer with a proton donating group on the enzyme. Such a van der Waals interaction might be expected to produce a stereoselective dipolar effect on the relaxation rates of the methyl group of L-phospholactate, but not of D-phospholactate. The present paper reports such a stereoselective effect and examines its properties. Experimental Section Materials. Rabbit muscle pyruvate kinase and lactate dehydrogenase were purchased from Boehringer und Sohne (Mannheim, West Germany). The NADH and P-enolpyruvate were purchased from Sigma and 2-phosphoglycolate was purchased as the tricyclohexylammonium salt from General Biochemicals, Chagrin Falls, Ohio. Spectroscopically pure MgO was obtained from Johnson Matthey Chemicals, Ltd., London, England, and was neutralized with DCl to form contaminant-free MgC12.D- and L-phospholactate were synthesized as previously described (Nowak and Mildvan, 1970). The analogues of P-enolpyruvate were converted to their K+-free form by passage through a Dowex 50-H+ column and the material collected as the free acid. This was then 1 Abbreviations used are: P-enolpyruvate, phosphoenolpyruvate; TMA, tetramethylammonium cation.

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4

A

3.0 u)

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FIGURE 1 : The effect of pyruvate kinase on the proton nuclear magnetic resonance spectra of the methyl groups L-phospholacetate (L-PL) and D-phospholactate (D-PL) in the absence of a divalent cation and KCI at 100 MHz. The phospholactates were present as their Tris salts in 99.6% D20 (A and E). Enzyme was added as a solution in 0.05 M Tris-C1(pH 7.5) buffer in DzO(B and F ; EDTA was added as the trisodium salt in H 2 0 (C); and Penolpyruvate added as the Tris salt in DzO (D). The initial volumes were 0.4 rnl and the temperature was 30 i 1 '.

neutralized either with tetramethylammonium hydroxide or Tris base. Methods. Pyruvate kinase, assayed as previously described (Tietz and Ochoa, 1958), had a specific activity of 110-150 unitsimg and was judged by acrylamide gel electrophoresis to be a t least 98% pure. In the nmr experiments where the relaxation rates of the carbon-bound protons of the P-enolpyruvate analogs were measured, the enzyme was desalted as previobsly described (Nowak and Mildvan, 1970), lyophilized, and redissolved in distilled 99.8 % D20. The lyophilization and solution in D 2 0were repeated twice. In experiments where the relaxation rates of the 31P nucleus were measured, the solutions were desalted, concentrated by vacuum dialysis, diluted with D 2 0 for field locking, and passed through a small Chelex column prior t o use to remove any trace paramagnetic metal contaminants. The nmr spectra were taken either on a Varian HA-100-15 or a Varian XL-100-15 nmr spectrometer, and on the Varian HA-220 spectrometer. The 1/T2data were obtained from measurements of the half-width of the resonance signal a t half-height a t 5 dB or more below saturation and liT, was obtained by measuring the power at which the signal saturates, as described elsewhere (Mildvan and Cohn, 1970).

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FlGURE 3 : P-enolpyruvate competition with L-phospholactate for pyruvate kinase in the presence and absence of KCI. (A) The effect of 338 PM pyruvate kinase sites on the line width of the methyl resonance of the Tris salt of L-phospholactate (61.4 mM) in 99% D 2 0 (pH 7.5) is titrated with Tris-P-enolpyruvate added as a solution in D 2 0(pH 7.5). The points represent the observed line widths and the solid curve is computed by assuming competition between P-enolpyruvate (KL = 0.40 mM) and L-phospholactate (K3 = 1.0 mM). (B) The effect of 135 ,UM pyruvate kinase sites on the line width of the methyl resonance of the K' salt of L-phospholacetate (50 mht) in 99% D20 (pH 7.5) is titrated with P-enolpyruvate added as a solution in DzO(pH 7.5). The points represent the observed line widths and the solid curve is computed by assuming competition between P-enolpyruvate (Ks= 0.15 mM) and L-phospholacetate ( K = 0.20 mM). Temperature = 30 1 1".

With the analogs, L-phospholactate and phosphoglycolate large diamagnetic effects of pyruvate kinase on the relaxation rates of the protons and phosphorus were observed, comparable in magnitude t o paramagnetic effects (Nowak and Mildvan, 1972). These diamagnetic effects were expressed quantitatively in a manner analogous with paramagnetic effects (Mildvan and Cohn, 1970). Thus the diamagnetic effects on the relaxation rates (1/Tld, 1/T2d)were calculated by subtracting the relaxation rates observed in absence of enzyme (l/T,ca,, 1/T2(o, from those observed in its presence (l/Tl(o,,rc~)r l/T*(obsd)), and the values of l/T,d and 1/T2d so obtained were normalized by the factor f = [diamagnetic sites]/[ligand] (eq 1 and 2). The normalization assumes saturation by ligands

at equivalent, noninteracting sites, a n assumption justified by the data. The site concentration was calculated assuming a protein molecular weight of 237,000 (Warner, 1958) and four active sites per molecule (Reuben and Cohn, 1970; Cottam and Mildvan, 1971). Results and Discussion

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[Pyruvate Kinase Sites] (mM) 2: The effect of pyruvate kinase on the transverse relaxation rate of the methyl protons of L-phospholacetate. The transverse of the methyl group of L-phospholacetate (50 relaxation rate (1/T2) mM) was measured at 100 MHz at varying concentrations of pyruvate kinase. Temperature = 30 =k 1 '. FlGURE

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Diamagnetic Efects of Pyruoate Kinase on the Relaxation Rates of the Methyl Protons of L- and D-Phospholactate. The proton nuclear magnetic resonance spectrum of the L- (and D-) phospholactate a t 100 MHz has previously been described (Nowak and Mildvan, 1970). Only the methyl doublet (6 = 1.82 ppm downfield from tetramethylsilane; J = 7 Hz) was suitable for relaxation rate measurements (Figure 1). Metalfree pyruvate kinase broadens the methyl resonance of Lphospholactate due to a n increase in the transverse relaxation rate (l/T2) and increases the radiofrequency power required to saturate these resonances due to an increase in the longitudinal (l/Tl) and transverse relaxation rates of the

HINDERED MOTION OF ENZYME-BOUND

SUBSTRATE ANALOGS ~~~~

TABLE I :

Effect of Pyruvate Kinase on theRelaxation Rates of the Magnetic Nuclei of PhosphoenolpyruvateAnalogs.

Analog L-Phospholactateb

D-Phospholactateb Phosphoglycolate

Additionsa PKe PK PK PK PK PK

+ Na3EDTA + K+ + Kf + EDTA

PK

+ K+

1/fTzd

l/fTid 0.65 f 0.15 0.36 f 0.15 0.11 i 0.03 0.11 f 0.03 0.23 i 0.10 0 f 0.02 0.028 i 0.003d 0 f 0.02

T~ (sec

1.80 f 0.20 1.65 i 0.20 0.87 f 0.10 0.72 i 0.10 0.29 f 0.07 0.79 f 0.10 6.00 j= l . O d 0.75 i 0.10

X 109)

1.7 f 0.4 2.6 f 0.4 3.8 f 0.1 3.4 i 0.2 50.5 2.11 66 f 6 2 10

a Conditions and concentrations are as described in Figure 1. K+, when present, was added as KCI at a final concentration of 0.1 M. The relaxation rates of the methyl protons in absence of enzyme are l/Tl = 1.05 i 0.08 sec-l and l/Tz = 2.93 i 0.10 sec-1. The relaxation rates of the methylene protons in absence of enzyme are l/Tl = 1.05 i 0.10 sec-l and l/Tz = 3.52 f 0.38 sec-1. Phosphorus nucleus studied at 40.5 MHz. The relaxation rates of this nucleus in absence of enzyme are l / T , = 0.0205 f 0.0020 sec-l and l/T2 = 2.58 f 0.12 sec-I. e PK = pyruvate kinase.

methyl protons (Figure 1B). The observed transverse relaxation rate is directly proportional to enzyme concentration (Figure 2) indicative of an interaction of the ligand with the enzyme. The diamagnetic effect of the enzyme on the relaxation rates of the methyl protons of L-phospholactate are decreased by the addition of P-enolpyruvate (Figure 1D). A titration of the effect of P-enolpyruvate on the diamagnetic line broadening in the absence of K+ (Figure 3A) can be fit by assuming competition between P-enolpyruvate (Ks = 0.40 mM) and Lphospholactate (Ks= 1.0 mM). The K, for P-enolpyruvate is similar to the value obtained independently, in the absence of activating monovalent and divalent cations, by ultraviolet (uv) difference spectroscopy (0.25 mM, Suelter et al., 1966). The K , value for L-phospholactate is in reasonable agreement with the dissociation constant estimated independently by analyses of titrations in which the proton relaxation rate of water was measured (3.5 f 1.5 KIM, Nowak and Mildvan, 1972). In the presence of K+ (Figure 3B) a titration of the L-phospholactate complex with P-enolpyruvate can also be fit by assuming competition between P-enolpyruvate (Ks = 0.1 5 mM) and L-phospholactate (Ks = 0.20 mM). The former value is in reasonable agreement with the dissociation constants determined by uv difference spectroscopy (0.08 mM) (Suelter et a[., 1966) and by kinetic analysis (0.05 mM) (Mildvan and Cohn, 1966). The K, of L-phospholactate is somewhat smaller than the value estimated by analysis of titrations in which the proton relaxation rate of water was measured (1.5 i 0.9 mM, Nowak and Mildvan, 1972). However, the latter value is based on the concentration of minor components in an equilibrium which includes enzyme-Mn complexes. These competition studies thus suggest that the diamagnetic effects of the enzyme on the relaxation rates of the methyl protons of L-phospholactate take place at the P-enolpyruvate binding site of pyruvate kinase and represent an active-site phenomenon. In sharp contrast with the marked diamagnetic effect on the methyl protons of L-phospholactate, a negligibly small diamagnetic effect is observed on the methyl protons of Dphospholactate (Figure 1F). Table I summarizes the diamagnetic effects of pyruvate kinase on the relaxation rates of the

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4: Arrhenius plot of the temperature dependence of the effect of pyruvate kinase on the 1/Tld and 1/T2d of the methyl group of L-phospholacetate.The reciprocal temperaturedependences of the logarithm of the relaxation rates are fit by assuming that the correlation time (r0)of the methyl group decreases with increasing temperature with an activation energy (Ea) of 1.8 kcal/mole. FIGURE

carbon-bound protons of the analogues. The enzyme produces significantly larger diamagnetic effects on the methyl protons of L-phospholactate than on those of D-phospholactate (Table I) (Figure l). Thus the effect of pyruvate kinase on the methyl resonance of L-phospholactate is stereoselective. The weaker binding of the L isomer had previously been explained by steric interaction of its methyl group with a proton donatB I O C H E M I S T R YV ,O L . 11,

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ing group on pyruvate kinase which protonated the substrate, P-enolpyruvate. Since the line broadening might be due to hindered rotation of the methyl group resulting from this steric interaction, a more detailed study of the diamagnetic effects of pyruvate kinase on the longitudinal ( l / f T l d )and transverse ( I / fT2d) relaxation rates of the methyl resonance of L-phospholactate was made. Effect of EDTA and Acfifiating Cations on the Diamagnetic Relaxation Rates of L-Phospholactate. As shown in Table I and Figure IC, the relaxation rates are essentially unaffected by 10 mM EDTA which renders unlikely the possibility that they are due to trace paramagnetic metal contaminants. The monovalent activator significantly lowers the diamagnetic effects (Table I). In experiments not shown, 20 /IM MgC12prepared from spectroscopically pure MgO had no effect on l/fT,d and l/fT2d of L-phospholactate in the presence or absence of K+, but 10 /IM MnClz increases both relaxation rates due to its paramagnetic effects as shown elsewhere (Nowak and Mildvan, 1972). Effect of Temperature and Frequency on the Diamagnetic Reluxation Rates of L-Phospholactate. Figure 4 shows a negative temperature coefficient of l/fT1d and l,lfT2d at 100 MHz and a decrease in l/fT2d upon changing the frequency of observation from 100 to 220 MHz, indicating that the observed line broadening is due to a change in the relaxation rate rather than to a change in the chemical shift of bound L-phospholactate. The negative temperature dependence is indicative of the rapid exchange of L-phospholactate into the diamagnetic environment of the enzyme, at a rate which is greater than l/fT2d(>lo3 sec-l). From the relationship for the chemical shift mechanism with rapid exchange (Swift and Connick, 1962), we may write (3)

where T B is the residence time and AWB is the change in the chemical shift of the ligand in the diamagnetic environment of the enzyme. From eq 3 a 4.8-fold greater value of l/fT2d at 220 MHz than at 100 MHz would have been expected since AWB is directly proportional to the frequency of observation. Because the opposite effect of frequency is observed (Figure 4), the shift mechanism is excluded. Hence, the dipolar relaxation mechanism is operative and l/fT2dand l/fT]d measure the relaxation rates of a bound molecule of L-phospholactate, for which the relevant equations for a three-spin system, derived in a manner similar to those previously derived for a two-spin system (Abragam, 1967; Solomon, 1955), are

In eq 4 and 5 is the gyromagnetic ratio of the proton, Z is the nuclear spin quantum number (1/2 for protons), w I is the proton resonance frequency, r is the interproton distance, and r, is the correlation time for proton-proton dipolar interaction. From the ratio of l,/fT2dat 100 and 220 MHz (1.5 i.

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0.2) a correlation time, presumably the methyl rotation time2 sec, is calculated at 18" from eq 5 . T , = 1.5 + 1.0 X From the ratio of l:fTld at 100 and 220 MHz (3.19 0.24) a correlation time T~ = 1.3 i 1.0 X l o p y sec is calculated from eq 4, in agreement with the value calculated from the T2data. From the ratio of T:d/T2d at 100 MHz, a separate calculation of r Ccan be made from eq 6 which is derived from eq 4

*

*

and 5 above. Using eq 6 and the ratio Tld/T2d = 1.62 0.18 at 18" and at 100 MHz yields a value of T~ = 0.9 i. 0.2 X l o p 9sec in agreement with the approximate values calculated from the frequency dependence. These values are reasonable time constants for a hindered methyl rotation. Hindered methyl rotation is the only motion in this system with a time constant of this order which could modulate dipolar proton-proton interactions and thereby serve as the correlation time.2 Since the value of T , for unhindered rotation would be expected to be